US10988275B2 - Package feedback control system and associated methods - Google Patents

Package feedback control system and associated methods Download PDF

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US10988275B2
US10988275B2 US16/613,244 US201816613244A US10988275B2 US 10988275 B2 US10988275 B2 US 10988275B2 US 201816613244 A US201816613244 A US 201816613244A US 10988275 B2 US10988275 B2 US 10988275B2
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index level
level
levels
product
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US20200115090A1 (en
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Daniel D. Bean
William R. Wilson
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Cryovac LLC
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Cryovac LLC
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B57/00Automatic control, checking, warning, or safety devices
    • B65B57/10Automatic control, checking, warning, or safety devices responsive to absence, presence, abnormal feed, or misplacement of articles or materials to be packaged
    • B65B57/14Automatic control, checking, warning, or safety devices responsive to absence, presence, abnormal feed, or misplacement of articles or materials to be packaged and operating to control, or stop, the feed of articles or material to be packaged
    • B65B57/145Automatic control, checking, warning, or safety devices responsive to absence, presence, abnormal feed, or misplacement of articles or materials to be packaged and operating to control, or stop, the feed of articles or material to be packaged for fluent material
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B9/00Enclosing successive articles, or quantities of material, e.g. liquids or semiliquids, in flat, folded, or tubular webs of flexible sheet material; Subdividing filled flexible tubes to form packages
    • B65B9/10Enclosing successive articles, or quantities of material, in preformed tubular webs, or in webs formed into tubes around filling nozzles, e.g. extruded tubular webs
    • B65B9/20Enclosing successive articles, or quantities of material, in preformed tubular webs, or in webs formed into tubes around filling nozzles, e.g. extruded tubular webs the webs being formed into tubes in situ around the filling nozzles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B1/00Packaging fluent solid material, e.g. powders, granular or loose fibrous material, loose masses of small articles, in individual containers or receptacles, e.g. bags, sacks, boxes, cartons, cans, or jars
    • B65B1/30Devices or methods for controlling or determining the quantity or quality or the material fed or filled
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B3/00Packaging plastic material, semiliquids, liquids or mixed solids and liquids, in individual containers or receptacles, e.g. bags, sacks, boxes, cartons, cans, or jars
    • B65B3/26Methods or devices for controlling the quantity of the material fed or filled
    • B65B3/28Methods or devices for controlling the quantity of the material fed or filled by weighing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B51/00Devices for, or methods of, sealing or securing package folds or closures; Devices for gathering or twisting wrappers, or necks of bags
    • B65B51/32Cooling, or cooling and pressing, package closures after heat-sealing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B57/00Automatic control, checking, warning, or safety devices
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B9/00Enclosing successive articles, or quantities of material, e.g. liquids or semiliquids, in flat, folded, or tubular webs of flexible sheet material; Subdividing filled flexible tubes to form packages
    • B65B9/10Enclosing successive articles, or quantities of material, in preformed tubular webs, or in webs formed into tubes around filling nozzles, e.g. extruded tubular webs
    • B65B9/20Enclosing successive articles, or quantities of material, in preformed tubular webs, or in webs formed into tubes around filling nozzles, e.g. extruded tubular webs the webs being formed into tubes in situ around the filling nozzles
    • B65B9/2007Means for stripping or squeezing filled tubes prior to sealing to remove air or products from sealing area
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B9/00Enclosing successive articles, or quantities of material, e.g. liquids or semiliquids, in flat, folded, or tubular webs of flexible sheet material; Subdividing filled flexible tubes to form packages
    • B65B9/10Enclosing successive articles, or quantities of material, in preformed tubular webs, or in webs formed into tubes around filling nozzles, e.g. extruded tubular webs
    • B65B9/20Enclosing successive articles, or quantities of material, in preformed tubular webs, or in webs formed into tubes around filling nozzles, e.g. extruded tubular webs the webs being formed into tubes in situ around the filling nozzles
    • B65B9/2014Tube advancing means
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65BMACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
    • B65B9/00Enclosing successive articles, or quantities of material, e.g. liquids or semiliquids, in flat, folded, or tubular webs of flexible sheet material; Subdividing filled flexible tubes to form packages
    • B65B9/10Enclosing successive articles, or quantities of material, in preformed tubular webs, or in webs formed into tubes around filling nozzles, e.g. extruded tubular webs
    • B65B9/20Enclosing successive articles, or quantities of material, in preformed tubular webs, or in webs formed into tubes around filling nozzles, e.g. extruded tubular webs the webs being formed into tubes in situ around the filling nozzles
    • B65B9/207Enclosing successive articles, or quantities of material, in preformed tubular webs, or in webs formed into tubes around filling nozzles, e.g. extruded tubular webs the webs being formed into tubes in situ around the filling nozzles the web advancing continuously

Definitions

  • the presently disclosed subject matter relates generally to a system and associated methods for controlling and maintaining consistency of the volume of product contained within product packages. More specifically, embodiments herein describe a feedback control system that can adjust package feed and product dispensing settings to maintain precise product volume control for systems that package the product within flexible pouches.
  • VFFS packaging systems have proven to be very useful in packaging a wide variety of food and non-food pumpable and/or flowable products.
  • Many vertical form/fill/seal systems are commercially available from manufacturers or suppliers such as Hayssen, Illipak, Kartridge Pak, DuPont and Fresco.
  • thermoplastic film is advanced over a forming device to form a tube, a longitudinal (vertical) fin or lap seal is made, and a bottom end seal is made by transversely sealing across the tube with heated seal bars.
  • a liquid, flowable, and/or pumpable product such as a liquid, semiliquid, or paste, with or without particulates therein, is introduced through a central, vertical fill tube to the formed tubular film. Squeeze rollers spaced apart and above the bottom end seal squeeze the filled tube and pinch the walls of the flattened tube together.
  • the process can be a two-stage process where the creation of a transverse heat seal occurs at one stage in the process, and then, downstream of the first stage, a separate pair of cooling/clamping means contact the just-formed transverse heat seal to cool and thus strengthen the seal.
  • VFFS processes an upper transverse seal of a first pouch, and the lower transverse seal of a following pouch, are made, and the pouches cut and thereby separated between two portions of the transverse seals, without the need for a separate step to clamp, cool, and cut the seals.
  • a commercial example of an apparatus embodying this more simplified process is the ONPACKTM 3002 VFFS packaging machine marketed by Cryovac/Sealed Air Corporation. In either type of VFFS process, variations in the volume of product filling the individual pouches is undesirable. Thus, it would be desirable to provide more precise product volume control in these conventional systems.
  • Embodiments of the presently disclosed subject matter are directed to a method and apparatus for producing product packages comprising operating first and second feedback control loops where product package weight is averaged and used to determine one of two possible adjustments to change the fill rate of the product package and the volume of the product.
  • the feedback loops operate in one of a plurality of index levels.
  • the first feedback loop seeks to improve performance by making adjustments to the fill rate and volume of the product, while incrementally moving to more stable index levels requiring tighter tolerances and package weight averages based on more product packages.
  • the second feedback loop seeks to preserve stability by making its own adjustments to the fill rate and volume of the product if large product package weight fluctuations are sensed.
  • the second feedback loop can move operation to less stable index levels having wider tolerances and package weight averages based on fewer product packages.
  • a method for producing on an apparatus a plurality of product packages by adjusting on an ongoing basis a fill rate at which the product is filled and a corresponding product volume contained within the pouch. While operating the apparatus in one of a plurality of index levels, the method comprises forming, filling, and sealing the product packages using initial values for the fill rate and the volume and measuring a weight of the product packages as they are produced by the apparatus.
  • the method may comprise calculating, based in part on the measured weights, a first adjusted measure of the fill rate and a first adjusted measure of the volume, and comparing the first adjusted measure of volume against a plurality of first threshold levels, each first threshold level corresponding to one of the plurality of index levels, the first threshold levels comprising a widest first threshold range at a first index level and a narrowest first threshold range at a second index level.
  • the method may comprise calculating, based in part on the measured weights, a second adjusted measure of the fill rate and a second adjusted measure of the volume and comparing the measured weight against a plurality of second threshold levels, each second threshold level corresponding to one of the plurality of index levels, the second threshold levels comprising a widest second threshold range at the first index level and a narrowest second threshold range at the second index level.
  • the plurality of first and second threshold levels may comprise more than two levels with intermediate levels between the first and second index levels having tolerance ranges between the narrowest and widest tolerance ranges.
  • the apparatus may be adjusted using the first adjusted measure of the fill rate and the first adjusted measure of the volume and the index level may be changed in a direction from the first index level towards the second index level.
  • the index level change in this direction may be changed by a single index level.
  • the apparatus may be adjusted using the first adjusted measure of the fill rate and the first adjusted measure of the volume and the index level may be changed in a direction from the second index level towards the first index level.
  • the index level change in this direction may be changed by one or more index levels.
  • the apparatus may be adjusted using the second adjusted measure of the fill rate and the second adjusted measure of the volume and the index level may be changed by one or more levels in the direction from the second index level towards the first index level.
  • the first and second adjusted measures of the volume are an adjusted squeeze close length and the first and second adjusted measures of the fill rate are an adjusted pump speed of a pump that dispenses product into the pouch.
  • the step of calculating the first adjusted measure of the fill rate and the first adjusted measure of the volume comprises averaging a different number of the measured weights for each of the plurality of index levels, including averaging a smallest number of the measured weights at the first index level and averaging a largest number of the measured weights at the second index level.
  • the step of calculating the second adjusted measure of the fill rate and the second adjusted measure of the volume comprises averaging a different number of the measured weights for each of the plurality of index levels, including averaging a smallest number of the measured weights at the first index level and averaging a largest number of the measured weights at the second index level.
  • the step of calculating the second adjusted measure of the fill rate and the second adjusted measure of the volume comprises averaging a first number of the measured weights and the step of calculating the first adjusted measure of the fill rate and the first adjusted measure of the volume comprises averaging a larger second number of the measured weights.
  • these steps may be implemented as a computer program for instructing a computer to perform the method.
  • Another embodiment comprises a computer-implemented method for producing on an apparatus a plurality of product packages by adjusting on an ongoing basis a fill rate at which the product is filled and a corresponding product volume contained within the pouch.
  • the computer implemented method may be executed on a processor and comprise operating the apparatus in one of a plurality of index levels, and at each level forming, filling, and sealing the product packages using initial values for the fill rate and the volume and measuring a weight of the product packages as they are produced by the apparatus.
  • the processor may calculate, based in part on the measured weights, a first adjusted measure of the fill rate and a first adjusted measure of the volume and compare the first adjusted measure of volume against a plurality of first threshold levels, each first threshold level corresponding to one of the plurality of index levels, the first threshold levels comprising a widest first threshold range at a first index level and a narrowest first threshold range at a second index level.
  • the processor may calculate, based in part on the measured weights, a second adjusted measure of the fill rate and a second adjusted measure of the volume and compare the measured weight against a plurality of second threshold levels, each second threshold level corresponding to one of the plurality of index levels, the second threshold levels comprising a widest second threshold range at the first index level and a narrowest second threshold range at the second index level.
  • the processor may adjust the apparatus using the first adjusted measure of the fill rate and the first adjusted measure of the volume and change the index level by a single index level in a direction from the first index level towards the second index level.
  • the processor may adjust the apparatus using the first adjusted measure of the fill rate and the first adjusted measure of the volume and change the index level by one or more index levels in a direction from the second index level towards the first index level.
  • the processor may adjust the apparatus using the second adjusted measure of the fill rate and the second adjusted measure of the volume and change the index level by one or more index levels in a direction from the second index level towards the first index level.
  • the first and second adjusted measures of the volume are an adjusted squeeze close length. In one embodiment, the first and second adjusted measures of the fill rate are an adjusted pump speed of a pump that dispenses product into the pouch. In one embodiment, the step of calculating the first and second adjusted measures of the fill rate and the first and second adjusted measures of the volume comprises averaging a different number of the measured weights for each of the plurality of index levels, including averaging a smallest number of the measured weights at the first index level and averaging a largest number of the measured weights at the second index level.
  • the step of calculating the second adjusted measure of the fill rate and the second adjusted measure of the volume comprises averaging a first number of the measured weights and the step of calculating the first adjusted measure of the fill rate and the first adjusted measure of the volume comprises averaging a larger second number of the measured weights.
  • Another embodiment comprises an apparatus for producing a plurality of product packages by a process of forming product pouches from a film, filling the pouches with a product, and sealing the product pouches to form the product packages, the apparatus comprising a film feed controller and feed mechanism in contact with the film to advance the film a desired amount to create a pouch having a desired volumetric capacity, a product dispense controller disposed to supply a desired, adjustable volume of product to the pouches formed from the film, a squeeze controller and squeeze mechanism in contact with the film to restrict a flow of product supplied by the dispense controller into the pouches formed from the film, a product package scale disposed in-line with a conveyor system that carries the product packages away from the apparatus, the product package scale measuring a weight of the product packages produced by the apparatus, and a computer processor adapted to operate at least first and second feedback loops.
  • the processor may operate the first feedback control loop and second feedback control loop in one of a plurality of index levels.
  • the processor may receive the weight of the product packages and calculate, in the first feedback loop, a first average of the weights and determine a first squeeze controller adjustment and optionally a first product dispense controller adjustment.
  • the processor may calculate, in the second feedback loop, a second average of the weights and determine a second squeeze controller adjustment and optionally a second product dispense controller adjustment.
  • the processor may compare the first squeeze controller adjustment against a plurality of first threshold levels, each first threshold level corresponding to one of the plurality of index levels, the first threshold levels comprising a widest first threshold range at a first index level and a narrowest first threshold range at a second index level.
  • the processor may compare the second average of the weights against a plurality of second threshold levels, each second threshold level corresponding to one of the plurality of index levels, the second threshold levels comprising a widest second threshold range at the first index level and a narrowest second threshold range at the second index level.
  • the processor may apply the first squeeze controller adjustment and optionally the first product dispense controller adjustment to the production of new product packages and change the index level by a single index level in a direction from the first index level towards the second index level. If instead the first squeeze controller adjustment is outside of the current first threshold level corresponding to the current index level, the processor may apply the first squeeze controller adjustment and optionally the first product dispense controller adjustment to the production of new product packages and change the index level by one or more index levels in a direction from the second index level towards the first index level.
  • the processor may apply the second squeeze controller adjustment and optionally the second product dispense controller adjustment to the production of new product packages and change the index level by one or more index levels in a direction from the second index level towards the first index level.
  • the steps of calculating the first and second averages of the weights comprises averaging a different number of the measured weights at each of the plurality of index levels, including averaging a smallest number of the measured weights at the first index level and averaging a largest number of the measured weights at the second index level.
  • the second average of the weights is calculated from a smaller number of package weights than the first average of the weights.
  • FIG. 1 is a diagrammatic representation of a VFFS process and apparatus for making a package in accordance with some embodiments of the presently disclosed subject matter;
  • FIG. 2 is an electro-mechanical schematic representation of a VFFS process and apparatus for making a package in accordance with some embodiments of the presently disclosed subject matter;
  • FIG. 3 is a process flow diagram, including parallel feedback control loops for a VFFS process and apparatus for making a package in accordance with some embodiments of the presently disclosed subject matter;
  • FIG. 4 is a graphical representation of package feed length tolerance levels at various index levels in accordance with some embodiments of the presently disclosed subject matter
  • FIG. 5 is a graphical representation of package weight tolerance levels at various index levels in accordance with some embodiments of the presently disclosed subject matter.
  • FIGS. 6A and 6B are schematic views representing operation of squeeze rollers, seal bars, and cut off knife on a VFFS apparatus in accordance with some embodiments of the presently disclosed subject matter.
  • Embodiments herein describe a feedback control system that can adjust package feed timing and product dispensing settings to maintain precise product volume control for systems that package the product within flexible pouches.
  • VFFS Vertical form/fill/seal
  • Such VFFS packaging systems may also use a pair of squeeze rollers to precisely control the volume of product contained within a given length of a pouch.
  • the VFFS packaging system may also dispense the product into the pouch at a desired rate so that each pouch is filled with a desired volume of product. The filled pouch is sealed and cut to form a final package.
  • Embodiments herein describe a feedback control system that tracks a characteristic of the packages and continually adjusts the product volume and dispensing rate to achieve consistent product volumes contained within the packages.
  • film can be used in a generic sense to include a thermoplastic film, laminate, sheet, or web, either multilayer or monolayer, and of any suitable thickness that may be used in connection with the present invention.
  • filled refers to an item (such as a pouch) that has been occupied with a product in a manner consistent with a commercial filling operation.
  • a pouch may or may not be 100% filled.
  • suitable flexible materials can be characterized by a modulus of less than about 50,000 PSI and in some embodiments less than 40,000 PSI (ASTM D-872-81).
  • uch refers to any of the wide variety of containers known in the art, including (but not limited to) bags, packets, packages, and the like.
  • the term “seal” refers to any seal of a first region of an outer film surface to a second region of an outer film surface, including heat or any type of adhesive material, thermal or otherwise.
  • the seal can be formed by heating the regions to at least their respective seal initiation temperatures.
  • the sealing can be performed by any one or more of a wide variety of methods, including (but not limited to) using a heat seal technique (e.g., melt-bead sealing, thermal sealing, impulse sealing, dielectric sealing, radio frequency sealing, ultrasonic sealing, hot air, hot wire, infrared radiation).
  • a heat seal technique e.g., melt-bead sealing, thermal sealing, impulse sealing, dielectric sealing, radio frequency sealing, ultrasonic sealing, hot air, hot wire, infrared radiation.
  • any direction referred to herein, such as “top,” “bottom,” “left,” “right,” “upper,” “lower,” and other directions and orientations are described for clarity in reference to the figures and are not to be limiting. It is to be understood that the films or systems described herein can be used in a wide variety of directions and orientations.
  • compositional percentages used herein are presented on a “by weight” basis, unless designated otherwise.
  • FIG. 1 schematically illustrates a VFFS apparatus 5 that can be used in the process of making a product filled package 8 in accordance with the present invention.
  • VFFS packaging systems are generally well known to those of skill in the art, and described for example in U.S. Pat. No. 4,589,247 (Tsuruta et al), U.S. Pat. No. 4,656,818 (Shimoyama et al.), U.S. Pat. No. 4,768,411 (Su), U.S. Pat. No. 4,808,010 (Vogan), U.S. Pat. No. 5,467,581 (Everette), and U.S. Pat. No. 6,244,747 (Caudle), all incorporated herein by reference in their entirety.
  • Apparatus 5 utilizes a lay-flat film 6 to create a flexible container for the product 18 .
  • Product 18 is manually or mechanically supplied to the upper end portion of forming tube 20 via any conventional means, such as a funnel or dispensing line 22 .
  • product 18 is supplied to the VFFS apparatus 5 from a product container 24 .
  • the product 18 can be any food or non-food product, liquid, semi-liquid, or paste, e.g. flowable or pumpable high acid or low acid foods, such as tomato products, milk or dairy products, medical products, or the like.
  • Packages are formed in a lower portion of apparatus 5 .
  • Film 6 from which the packages are formed is advanced from a feed roller (not shown), over forming tube 20 (sometimes known as a “sailor's collar” or “forming collar”).
  • forming tube 20 sometimes known as a “sailor's collar” or “forming collar”.
  • first 2 and second 4 sides of the film 6 are brought together and subsequently joined with a longitudinal seal 16 formed by longitudinal heat sealing device 26 .
  • the film 6 takes the shape of a vertically-oriented film tube 28 .
  • the film 6 will travel vertically downward from the forming tube 20 towards the lower portion of apparatus 5 , where transverse heat seal bars 32 , 34 operate to close and seal horizontally across the lower end of film tube 28 , to form a pouch 10 having a first transverse seal 12 . Pouch 10 is thereafter filled with product 38 .
  • Film feed mechanism 30 advances the film tube 28 and pouch 10 downward a predetermined distance to create a pouch 10 having a length L.
  • Squeeze rollers may be incorporated to close on the moving film in order to meter the amount of product in the pouch and to void/clean the area where a transverse seal is to be applied.
  • Seal bars 32 , 34 close and seal horizontally across the lower end of film tube 28 to form a first transverse seal 12 at the bottom of the film tube 28 , while simultaneously sealing horizontally across upper end of sealed pouch 10 to form a second transverse seal 14 .
  • a cut-off knife 36 may be situated between upper 32 and lower 34 seal bars to sever a lower sealed pouch 10 from the bottom of upstream pouch 38 .
  • the VFFS apparatus 5 shown in FIG. 1 includes a dispense controller 40 that controls the amount and/or rate at which the product 18 is dispensed into the film tube 28 .
  • the dispense controller 40 can adjust the volume of product dispensed per package 8 .
  • the dispense controller 40 may be a pump or a pump controller that adjusts the volume and flow rate for the product 18 delivered from container 24 through the dispensing line 22 and into the pouch 10 within the VFFS apparatus 5 .
  • the pump may be any suitable device that moves product 18 by mechanical action and can include an of a variety of pump types, including for example positive displacement pumps, velocity pumps, centrifugal pumps, or gravity pumps.
  • a suitable pump controller may alter the operation of a pump to change the volume and flow rate for the product 18 delivered by such a pump.
  • a pump controller may change the pump operating speed, operating pressure, or pump duty cycle.
  • a pump controller may alter the operation of a pump by altering an operating voltage, signal modulation, or by digital signal processing.
  • the dispense controller 40 may be implemented as a valve or other flow restrictor in conjunction with a flow meter or other solutions that can accurately control the volume and flow rate for the product 18 delivered to the film tube 28 .
  • the VFFS apparatus 5 also includes a feed controller 42 that controls the length and/or rate at which the film tube 28 translated downward through the VFFS apparatus 5 .
  • the feed controller 42 can adjust the length L (and hence the overall capacity) of the packages 8 .
  • the feed controller 42 may be a motor or a motor controller that adjusts the translation length or rate for the film tube 28 within the VFFS apparatus 5 .
  • the motor may be any suitable device that causes the film feed mechanism 30 to advance the film tube 28 a desirable, but adjustable length L. Examples of motors that might be used in this application include servo motors, stepper motors, DC motors.
  • a suitable motor controller may alter the operation of a motor to change the feed length or rate for the film tube 28 advanced by the feed mechanism 30 .
  • a motor controller may change the motor operating speed, motor duty cycle, or the duration of time that a motor operates.
  • a motor controller may alter the operation of a motor by altering an operating voltage, signal modulation, or by digital signal processing.
  • the motor controller may be a micro controller or a dedicated control circuit.
  • the feed controller 42 may be implemented as mechanical clutch, or a temporarily engageable drive train translated by a solenoid for example, or other electro-mechanical solutions that can accurately control the feed length or rate for the film tube 28 within the VFFS apparatus 5 .
  • Precise control of the volume of product 18 that fills a given pouch 10 may be managed with squeeze rollers 62 and a squeeze length controller 64 shown in FIGS. 6A & 6B .
  • a packaging cycle may begin with a cut-off knife 36 situated between upper 32 and lower 34 seal bars severing a lower sealed pouch 10 from the bottom of upstream pouch 38 .
  • Other embodiments may include a two-stage process where the creation of a transverse heat seal occurs at one stage in the process, and then, downstream of the first stage, a separate pair of cooling/clamping bars contact the just-formed transverse heat seal to cool and strengthen the seal just prior to separating the lower pouch 10 from the upstream pouch 38 .
  • the upstream pouch 38 that is filled or is being filled with product 18 is advanced by feed mechanism 30 past a pair of opposed squeeze rollers 62 and also past the seal bars 32 , 34 and cut-off knife 36 to the position shown in FIG. 6B where the pouch 10 has a desired length L.
  • the squeeze length controller 64 causes the squeeze rollers 62 to move from the separated position shown in FIG. 6A towards the closed position shown in FIG. 6B .
  • the squeeze rollers 62 roll in synchronization with the feed mechanism 30 so that the film tube 28 does not stretch or crumple.
  • the squeeze rollers 62 cause the film tube 28 to collapse and evacuates product 18 from the top of lower pouch 10 .
  • the squeeze rollers 62 continue to rotate, keeping product 18 above the squeeze rollers 62 within the upstream pouch 38 , and allowing an evacuated region 66 of the film tube 28 to reach the seal bars 32 , 34 and cut-off knife 36 .
  • the seal bars 32 , 34 seal the top of pouch 10 and bottom of pouch 38 and the cut-off knife separates the lower pouch 10 from the upstream pouch 38 .
  • the squeeze rollers 62 move once again to the open position shown in FIG. 6A , which allows product 18 to fill the upstream pouch 38 .
  • the squeeze controller 64 causes the squeeze rollers 62 to close when the bottom of the lower pouch 10 has moved a predetermined, but adjustable length past the squeeze rollers. This length is referred to as a Squeeze Close Length and is referred to herein as “SCL” and represented by the dimension SCL in FIG. 6B .
  • SCL dimension can be increased by delaying the time at which the squeeze rollers 62 close.
  • SCL dimension can be decreased by advancing the time at which the squeeze rollers 62 close.
  • the closing trigger may be determined by a simple countdown timer, with knowledge of the speed at which the pouch 10 is moving downward through the VFFS apparatus 5 .
  • the squeeze rollers 62 may close after the rollers have rotated a certain number of rotations. In another embodiment, the squeeze rollers 62 may close in response to a sensed position of the pouch 10 , such as with optical sensors, cameras, and/or image processing programs. Regardless, the SCL and the diameter of the film tube 28 determine the volume of product 18 contained within the individual pouches 10 . Therefore, in one or more embodiments, the SCL may be adjusted on an ongoing basis using a feedback control system to achieve consistent product volumes contained within the packages 8 .
  • the squeeze controller 64 may be an actuator or an actuator controller that adjusts the position of the squeeze rollers 62 within the VFFS apparatus 5 .
  • the actuator may be any suitable device that causes the squeeze rollers to move between the open and closed positions. Examples of actuators that might be used in this application include servo motors, stepper motors, DC motors, linear motors, solenoids and the like.
  • a suitable actuator controller may be an electrical circuit, microcircuit, power relay and the like that controls, changes, or enables the operation of an actuator. Since the squeeze controller 64 manages the time at which the squeeze rollers 62 engage or disengage, a digital or analog timer may be used to implement changes in SCL.
  • the squeeze rollers 62 and squeeze controller 64 are linked by a drivetrain that may include, for example, gears, arms, bearing, springs and the like. Those skilled in the art will appreciate a number of means for carrying out the function and operation of the squeeze roller 62 .
  • FIG. 2 illustrates a schematic representation of the VFFS apparatus 5 and associated electrical or mechanical hardware used in carrying out embodiments of the invention.
  • the VFFS apparatus 5 includes a user interface 56 that allows a user to enter and adjust a variety of operating settings, including for example, target weights, units, package sizes, machine speed and the like.
  • the VFFS apparatus 5 will continually produce packages 8 filled with product 18 .
  • These packages 8 are delivered to a conveyor system 44 that carries the packages 8 towards a collection bin, for example, or optionally to operators, who may prepare the packages 8 for use or transport or other post-processing. Since the packages 8 are sealed, precise volume measurements of the product 18 are impractical and would require opening the pouch 10 .
  • the conveyor system 44 may include an in-line scale 46 that is able to quickly and accurately measure the weight of each package 8 that moves onto the scale 46 .
  • the scale 46 may be a conveyor scale adapted to weigh the packages 8 while actively or passively conveying the package 8 from an upstream part of the conveyor 44 to a downstream part of the conveyor 44 in a direction indicated by the arrow D 1 .
  • the scale 46 may be implemented as a belt weigher, a conveyor scale, and the like.
  • the scale 46 may use strain gauges, piezoelectric elements, or electromagnetic force restoration load cells and the like.
  • the scale 46 may include a dedicated scale computer 48 and optionally a user interface 50 to manage such tasks as calibration, zeroing, or adjusting timing of the weights.
  • the scale computer 48 may match timing of the VFFS apparatus 5 .
  • the scale computer 48 may simply provide package 8 weights as they are read by the scale 46 .
  • the computer 48 may take multiple measurements of a single package 8 while it is traversing the scale 46 and calculate a weight average. Moreover, since the package 8 is moving across the scale 46 leading to signal variations, the computer 48 may process or filter readings from the scale 46 for improved accuracy.
  • the measured weight for individual packages 8 is transmitted by the computer 48 to the VFFS apparatus 5 , and particularly to a VFFS computer 52 that tracks and uses the weights of the packages 8 to make ongoing minor adjustments to the dispense controller 40 and squeeze controller 64 to provide consistent, repeatable package 8 weights (and volume).
  • Communications between the scale 46 and computers 48 , 52 may be provided through commonly known peripheral bus channels, including for example serial buses, USB, RS-232, I2C or other communications infrastructures, such as Ethernet or wireless protocols including, for example, Bluetooth, WiFi, NFC, and the like.
  • the scale computer 48 and VFFS computer 52 are depicted as separate elements. In another embodiment, the function and operation of each may be implemented on a single, shared computer.
  • the VFFS computer 52 tracks separate product weight averages to determine how far the product weights stray from an expected or desired value. These two separate product weight averages, referred to herein as an indexing average and a rolling average respectively form a part of separate, independent feedback loops that are each capable of effecting changes to the dispense controller 40 and squeeze controller 64 . Changes to the dispense controller 40 and squeeze controller 64 that produce a corresponding change in product dispense volume are applied by writing adjusted control settings to a programmable logic controller (PLC) 54 or other process controller. The PLC 54 controls the dispense controller 40 and squeeze controller 64 with the new, adjusted settings to produce new packages 8 . The new packages 8 are weighed at scale 46 and the feedback process continues.
  • PLC programmable logic controller
  • the adjustment settings that are applied to the dispense controller 40 and squeeze controller 64 may be based on average measured weights from a predetermined number of preceding packages 8 produced by the VFFS apparatus 5 . As discussed above, the weights are collected and measured as data correlating to the desired volume in the packages 8 . An accurate correlation may require some information about the product 18 , which an operator can provide by entering information into the user interface 56 . One piece of information that is used in calculating appropriate dispense rate and squeeze roller timing is the density of the product at the dispensing temperature. An operator may use the scale 46 to measure the weight of a unit volume of product 18 . For example, the operator may weigh a gallon of product 18 and enter this weight into the user interface 56 .
  • Density Measured Weight/Volume Weighed (1)
  • Expected Weight Desired Volume ⁇ Density (2)
  • Pouch 10 size may be another piece of information that an operator can provide at the user interface 56 .
  • the length L of a pouch 10 that can hold the desired volume of product 18 will depend on the diameter of the forming tube 20 .
  • the forming tube 20 determines the diameter of the film tube 28 that is sealed to create individual pouches 10 .
  • the VFFS apparatus 5 can run with different size forming tubes 20 to accommodate different size packages 8 .
  • SCL Desired Volume/Cross Section Area (5) This initial estimate for SCL is based on a perfectly shaped cylinder. However, since the pouches 10 are sealed at first and second transverse seals 12 , 14 (see FIG.
  • the product 18 contained within the pouch 10 will not assume the shape of a perfect cylinder.
  • the initial estimate for SCL can be modified, perhaps by some nominal percentage increase to account for the package 8 shape.
  • the SCL of the packages 8 will be updated as necessary by the weight feedback control process described below. Specifically, a change in SCL can be requested by setting a new SCL value in the PLC 56 , which then controls the squeeze controller 64 to close the squeeze rollers 62 at a delayed or advanced time to create pouches 10 having a new product volume. Accordingly, a rough initial estimate of the SCL is sufficient.
  • Equation (2) Weight/(Density ⁇ Cross Section Area) (6)
  • the adjustment factor AF 1 can be made larger, thus making the proposed change in squeeze close length ( ⁇ SCL) smaller.
  • Some representative values for AF 1 are discussed in greater detail below and shown in Table I. If packages 8 are weighed and determined to be underweight, then the measured weight difference ( ⁇ Weight) will be a positive value and equation (7) will also produce a positive value for ⁇ SCL to delay the time at which the squeeze rollers 62 close and allow more product 18 into the pouch 10 . Similarly, if packages 8 are weighed and determined to be overweight, then the measured weight difference ( ⁇ Weight) will be negative and equation (7) will also produce a negative value for ⁇ SCL, which will advance the time at which the squeeze rollers 62 close and reduce the volume of product 18 in the pouch 10 .
  • a corresponding change in product 18 fill speed or fill rate can also be made so that the overall speed of the VFFS 5 can be maintained. That is, if packages 8 are determined to be overweight, then a shorter SCL can be requested and product can be dispensed by PLC 54 and dispense controller 40 at a lower rate. Similarly, if packages 8 are determined to be underweight, then a longer SCL can be requested and product can be dispensed by PLC 54 and dispense controller 40 at a faster rate.
  • the dispenser controller 40 adjusts a pump speed to control the amount and/or rate at which the product 18 is dispensed into the film tube 28 .
  • a faster pump speed will provide a larger volume of product 18 into the pouches 10 in a given amount of time.
  • a slower pump speed will fill a smaller volume of product 18 into the pouches 10 in the same amount of time.
  • an adjustment factor for calculating a new pump speed may be in the range between 0.8 and 0.99.
  • a difference ( ⁇ Weight) between an expected weight and a measured or averaged actual weight can be used to calculate a desired change in squeeze close length ( ⁇ SCL) to change the product volume within the pouches 10 and, in turn, also calculate a desired change in pump speed ( ⁇ Speed) to change the rate at which product 18 fills the new pouches 10 .
  • the change in SCL ( ⁇ SCL) is determined first and that change in SCL is then used to calculate a change in pump speed ( ⁇ Speed).
  • the adjustment to SCL may be the only adjustment made in response to the feedback control process.
  • the change in pump speed may be calculated first and that pump speed change may be used to calculate a corresponding change in SCL.
  • FIG. 3 illustrates a process flow diagram for the package weight feedback control system implemented by the VFFS apparatus 5 using the hardware configuration shown in FIG. 2 .
  • the process begins at step 300 , which may correspond to an initial power up and running of the VFFS apparatus 5 or a process restart following a setting change based on prior package 8 weight measurements.
  • a wait time is enforced at step 302 , which allows newly initialized or newly changed settings to be applied to newly formed packages 8 and further allow those packages 8 to reach the scale 46 .
  • FIG. 2 shows that two packages 8 are positioned on the conveyor 44 between the VFFS apparatus 5 and the scale 46 .
  • a wait time of 3 pouches may be enforced at step 302 .
  • the system may implement one or more global or macro checks to verify that packages 8 are being produced as expected. For instance, the system may verify that the package weights are within a very wide tolerance range (e.g., 25%-35% of expected weight) before using a particular weight in the feedback calculations. Though not common, it is possible for package weights to stray outside of this wide tolerance range. This may occur, for instance, when particulates or air pockets in the product 18 cause temporary fluctuations in dispensing volume. When such variations occur, the system will ignore the outlier data points (step 306 ) as not being a true indication of the package weights produced by the current settings.
  • a very wide tolerance range e.g. 25%-35% of expected weight
  • the VFFS apparatus 5 may also check to verify that a sufficient amount of product is filling the pouches 10 regardless of particular run settings. It is generally desirable for product integrity and shelf-life reasons for the product 18 to substantially fill the pouch 10 . To achieve this, the dispense controller 40 should fill the film tube 28 with product 18 to a level that is above squeeze rollers 62 . Of course, the product 18 should not rise to a level that is too high within the film tube 28 as to pose a spill risk. To maintain an appropriate product 18 level, the VFFS apparatus 5 may include one or more head level sensors 58 , 60 as shown generically in FIG. 1 .
  • the head level sensors 58 , 60 may be implemented as photodetectors, photo eyes, or other sensors types, including for example electromagnetic, capacitive, light, or non-visible proximity detectors.
  • an upper head level sensor 58 verifies that product 18 does not rise above a desired level within the film tube 28 while lower head level sensor 60 verifies that product 18 does not fall below a desired level within the film tube 28 .
  • a macro check routine determines that both upper and lower head level sensors 58 , 60 detect the presence of product 18 (overfill condition) or if neither head level sensor 58 , 60 detects the presence of product 18 (underfill condition)
  • the system may correct the dispense controller 40 settings and/or feed controller settings 42 and write those updated settings to the PLC 54 (step 308 ) for continued operation.
  • the macro checks are completed for each new package produced by the VFFS apparatus 5 .
  • the macro checks may be completed periodically, such as after a certain number of packages are produced, or each time a change is written to the PLC 54 .
  • each loop has the capability to send SCL and pump speed adjustment settings to the PLC 54 (step 308 or step 310 , respectively). Further, if a first loop initiates a change in squeeze close length and pump speed, the second loop is reset to step 300 and locked out from making any changes immediately following the changes set by the first loop. Instead, the wait time at step 302 is enforced, followed by any applicable macro checks before both loops continue operating again with the changes that were implemented by the first loop.
  • the Indexing Average Loop attempts to achieve stable package 8 production by gradually and incrementally adjusting the package 8 settings to meet tighter and tighter tolerances. Ideally, with minor adjustments and monitoring, the VFFS apparatus 5 will achieve a condition where the SCL, pump speed, weight, and volume reach a stable and optimal condition.
  • the Indexing Average Loop operates in one of a plurality of discrete Index Levels. In the illustrated embodiment, the Index Levels are depicted as levels IL 1 through IL 6 . In other embodiments, more or fewer levels may be used. Index Level 1 (IL 1 ) represents the most uncontrolled or least stable level where package 8 weight variations are expected to vary within a large tolerance range, depicted in FIG. 4 as +/ ⁇ F.
  • the tolerance ranges for the various Index Levels IL 1 -IL 6 respectively vary between +/ ⁇ F at IL 1 and +/ ⁇ A at IL 6 , with F representing the largest value and A representing the smallest value.
  • letters E, D, C, and B represent progressively smaller values between the maximum value F and the smallest value A.
  • the tolerance ranges for Index Levels IL 1 -IL 6 may represent a number of different measurable or calculable values.
  • the tolerance levels might represent tolerance ranges for weights or average weights measured by scale 46 .
  • FIG. 4 represents tolerance ranges expressed in mm, though other units of measure are contemplated.
  • the Indexing Average Loop will average a plurality of measured weights received from the scale 46 .
  • a new SCL and pump speed are calculated as described above and those new settings are written to the PLC 54 to adjust the product 18 volume contained in subsequent packages 8 . It may be desirable to rely on average weights (versus individual weights) for calculating the necessary adjustments because of variations in the various processes and functions carried out by the VFFS 5 and the scale 46 in producing and weighing packages 8 .
  • the number of package weights that are averaged varies depending on the current Index Level.
  • IL 1 is represents the most uncontrolled level where package 8 weight variations are expected to vary within a large tolerance range
  • a relatively small number of package 8 weights are averaged before making the next adjustment at step 310 .
  • the Indexing Average Loop may progressively advance from a more uncontrolled Index Level, such as IL 1 , to more controlled Index Levels, such as IL 2 -IL 6 .
  • the Indexing Average Loop will average weights for an increasing number of packages 8 .
  • Table I below represents the number of packages that are weighed and averaged before calculating and setting a new SCL and pump speed.
  • Table I also provides numerical values for the tolerance levels A-F shown in FIG. 4 , according to one particular embodiment.
  • Table I also shows values for the adjustment factor AF 1 that may be used in equation (7) to calculate a change in squeeze close length ( ⁇ SCL) that is based on measured package 8 weights. As indicated above, a larger adjustment factor AF 1 will produce a smaller relative change in ⁇ SCL. Thus, while the Indexing Average Loop is running in more controlled levels (e.g., IL 5 or IL 6 ), the Adjustment Factor AF 1 is the largest.
  • Adjustment Factor AF 1 is the smallest so that larger relative changes in SCL can be used to move the system towards a more stable condition.
  • Experimentation and operation of a particular VFFS apparatus 5 may reveal that slightly different values than those shown in Table I may be appropriate.
  • the Indexing Average Loop will enter an index check at step 314 to determine at which Index Level the Indexing Average Loop should operate.
  • the Indexing Average Loop compares the most recently calculated change in SCL written to the PLC 54 at step 310 against the tolerance ranges in FIG. 4 to determine whether the current performance is at or better than the current Index Level. So, for example, data point P 3 illustrates an example where a newly calculated change in SCL is within the expected tolerance range +/ ⁇ F for current Index Level IL 1 . Therefore, at step 320 , the Indexing Average Loop will change the current Index Level by one level from IL 5 to IL 6 .
  • Data point P 5 illustrates an example where a newly calculated change in SCL is within the expected tolerance range +/ ⁇ F for current Index Level IL 1 and also within the tighter tolerance range +/ ⁇ E for Index Level IL 2 . Therefore, at step 320 , the Indexing Average Loop will change the current Index Level by one level from IL 1 to IL 2 .
  • the index check routine may require two or more repeat instances where the current performance is better than the current Index Level before moving to the next, more accurate Index Level at step 320 . Upon repeated, improved performance, the Indexing Average Loop can ultimately operate at the most accurate index level IL 6 and remain at that level as long as the performance of the VFFS 5 continues to produce packages 8 meeting the tight tolerance +/ ⁇ A.
  • the Index Level will improve by a single step (IL+1) regardless of how much better the current performance is than the current Index Level. So for instance, data point P 4 represents a change in SCL that is within the expected tolerance level +/ ⁇ D for IL 3 and also within the expected tolerance ranges for each of Index Levels IL 4 -IL 6 . In spite of this good performance, the Indexing Average Loop will incrementally advance the current index level at step 320 from IL 3 to IL 4 . Such a small adjustment is appropriate where the objective of the Indexing Average Loop is to gradually and incrementally adjust the package 8 settings to meet tighter and tighter tolerances.
  • the Indexing Average Loop determines that the current system performance is worse than the current index level
  • the index check process continues to step 322 .
  • data point P 2 illustrates an example where a newly calculated change in SCL is outside of the expected tolerance range +/ ⁇ A for Index Level IL 6 .
  • data point P 2 does fall within the expected tolerance range +/ ⁇ B for Index Level IL 5 . Therefore, at step 322 , the Indexing Average Loop will move by one level from IL 6 to IL 5 .
  • the index check routine may require two or more repeat instances where the current performance is worse than the current Index Level before moving to a less accurate Index Level at step 322 .
  • the index check routine may require a single instance where the current performance is worse than the current Index Level before moving to a less accurate Index Level at step 322 .
  • a notable difference between step 320 and step 322 is that index level changes from a less accurate Index Level to a more accurate Index Level will proceed one level at a time.
  • the Indexing Average Loop may decrease the current Index Level by more than one level. So for instance, data point P 1 in FIG. 4 represents a change in SCL that is well outside of the expected tolerance level +/ ⁇ A for IL 6 . The only tolerance range this new change in SCL falls within is +/ ⁇ F for Index Level IL 1 .
  • the Indexing Average Loop will change the current Index Level from IL 6 to 11 _ 1 , which represents a change of five levels.
  • a rapid retreat of the Index Level is appropriate in an effort to implement necessary changes after smaller numbers of average package 8 weights.
  • a new adjustment value can be determined after the appropriate number of new packages 8 corresponding to the new Index Level (e.g., three packages for IL 1 ).
  • the Rolling Average loop operates as a watchdog check to make sure that adjustments implemented by the Indexing Average Loop do not cause the VFFS apparatus 5 to become unstable or begin to operate with a worse performance.
  • the Rolling Average Loop operates in one of a plurality of discrete Index Level ranges.
  • the Index Levels IL 1 through IL 6 are the same levels described above. However, the Rolling Average Loop operates in one of three levels. A first level corresponds to the most unstable Index Level IL 1 . A second level corresponds to intermediate Index Levels IL 2 -IL 3 . The third level corresponds to the more controlled levels IL 4 -IL 6 .
  • FIG. 5 shows that at the intermediate (IL 2 -IL 3 ) and controlled (IL 4 -IL 6 ) Index Level ranges, a Rolling Average of multiple package 8 weights is compared against tolerance ranges depicted respectively as +/ ⁇ 2% and +/ ⁇ Z %. In one embodiment, the Rolling Average of 3-6 package 8 weights is calculated and compared to the indicated tolerance ranges. In one embodiment, at all Index Levels, the Rolling Average of a fixed number of package 8 weights is calculated and compared to the indicated tolerance ranges. In one embodiment, the Rolling Average of varying numbers of package 8 weights is calculated and compared to the indicated tolerance ranges at different Index Levels.
  • a Rolling Average of three package 8 weights is calculated and compared against a tolerance of +/ ⁇ 2% of a desired, expected package 8 weight.
  • a Rolling Average of four package 8 weights is calculated and compared against a tolerance of +/ ⁇ 1% of a desired, expected package 8 weight.
  • the Rolling Average Loop will average (at step 324 ) a plurality of measured weights received from the scale 46 .
  • a new SCL and pump speed are calculated as described above. However, those new settings are not always written to the PLC 54 by the Rolling Average Loop to adjust the product 18 volume contained in subsequent packages 8 . If the current Rolling Average of package weights is better than or within the tolerance range for the current Index Level (step 326 ), the newly calculated values are ignored and the Rolling Average Loop simply returns to step 324 to continue averaging subsequent packages. Furthermore, the Rolling Average Loop does not seek to move the current Index Level to a more controlled Index Level.
  • data points P 8 , P 9 , and P 10 in FIG. 5 indicate that the current Rolling Average of package weights is better than or within the tolerance range for the current Index Level.
  • the Index Level is maintained at its current level in the range IL 4 -IL 6 (as determined by the Indexing Average Loop).
  • the Index Level is maintained at its current level in the range IL 2 -IL 3 (also as determined by the Indexing Average Loop).
  • the Rolling Average Loop does not change the current Index Level.
  • the Rolling Average Loop will change the current Index Level towards a less controlled or more unstable Index Level if the package 8 weights indicate a run of erratic or widely varying packages 8 .
  • data points P 6 , P 7 , and P 11 each indicate that the current Rolling Average of package weights are outside of the tolerance for their respective Index Level.
  • the current Index Level is in the range IL 4 -IL 6 and the Rolling Average weight should be within +/ ⁇ Z % of a desired weight.
  • Data point P 7 is outside of the +/ ⁇ Z % tolerance range, but is within +/ ⁇ Y % of the next lower, intermediate range of Index Levels IL 2 -IL 3 .
  • the Index Level is changed to IL 3 (step 328 ), and the new SCL and pump speed calculated at step 324 are written to the PLC 54 at step 308 .
  • Similar Index Level changes are applied after calculating and averaging the weights for data points P 6 and P 11 , which are each outside of the +/ ⁇ Y % tolerance range of the intermediate range of Index Levels IL 2 -IL 3 . Therefore, after calculating and averaging the weights for data points P 6 and P 11 , the Index Level is changed to IL 1 and the new SCL and pump speed calculated at step 324 are written to the PLC 54 at step 308 .
  • the Rolling Average may optionally perform or not perform a check against a tolerance level. As indicated, the Rolling Average Loop operates as a watchdog and only changes a current Index Level towards a less controlled level at step 328 as necessary. Thus, where IL 1 is the least controlled level, the Rolling Average Loop can simply operate at step 324 until such time as the Indexing Average Loop changes the current Index Level to IL 2 -IL 6 .

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US11565843B2 (en) * 2019-09-21 2023-01-31 Winpak Lane, Inc. Form fill seal system with multiple filling modes
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EP3625133A1 (fr) 2020-03-25
US20200115090A1 (en) 2020-04-16
WO2018213539A1 (fr) 2018-11-22

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